DE976057C - rocket - Google Patents

Description

Missile The invention relates to a missile or the like by Recoil driven by combustion gases, comprising a combustion chamber and a nozzle Device whose fuel and / or oxidizing agent are present in solid form are.

The burning speed and thus the thrust of this so-called Solid rocket is made by an appropriate mixture of solid oxidizing agents and solid fuels in finely divided, intimately mixed form determined, wherein high calorific fuels are used to achieve the greatest possible thrust will.

For ease of handling, the mixture becomes a solid than Propellant used compact compressed. Such propellants are very unstable and have only a short shelf life. Above all is these solid mixture propellants due to the risk of explosion at higher burn-off speeds Limit the thrust performance and thus its possible use.

These disadvantages are to be eliminated by the invention, according to the the fuel and / or the oxidizing agent are not finely divided with one another are mixed, but - separated from each other - in the form of more or less large pieces or volumes are provided.

In the simplest case, these pieces can be in the form of rods, cubes, Blocks used be, if necessary chemically with Protective coatings, separating lamellas or the like that do not react to them can be provided.

Because there is no reactive mixture of fuel and oxygen carrier is present, the risk of an explosion is avoided while at the same time considerable Increase in the thrust during the burn-off to be described.

According to the invention, those of the combustion chamber become the by recoil combustible gases to be supplied by combustion gases driven device in a smoldering chamber generated, the preferably gaseous oxidizing agent fed separately from the combustible gases to the combustion chamber.

In this smoldering burner containing a suitable smoldering body When this carbon dioxide burns down, flammable, volatile substances (gases, Vapors or aerosols). According to the invention, the cavernous body consists of solid, pasty or more or less liquid chemically uniform compounds or mixtures of such compounds, their content of active oxidizing agent is dimensioned so that on the one hand a stable imperfect combustion and on the other hand a certain smoldering speed is maintained under given conditions will.

The carbonization products should preferably burn the body leave without this requirement being mandatory. To a flow of a melting To prevent fuel, it can not melt substances - such. B. Dextrin or the like - are added.

The smoldering burner can contain polymers as fuel, in which the oxygen carriers required to maintain the smoldering process are incorporated are.

Various modifications can be chosen for the smoldering process. at of a shape it runs with such a warmth that a chemical substance with the release of volatile oxidizing agents - such. B. 02, N20 or other oxides of nitrogen, C12, C102 and the like is decomposed.

These oxidizing agents can be mixed with other decomposition products - such as B. H20, N2, HCl and others. - be mixed. Both the smoldering as well as the oxidizing agent-forming substance contain substances which the drainage regulate the chemical reactions in question in a predetermined manner or under the given conditions - z. B. low combustion chamber pressure, low outside temperatures i.a. -first enable.

Like the Schweler for the production of the combustible gases only a small one Addition of oxidizing agents required to maintain the smoldering process can contain, so you can in an analogous manner to the generation of the oxidizing gases or the like. Use an oxidizer that contains as little fuel as possible, ie "smoldering" with the release of oxidizing gases. In another embodiment of the smoldering burner, the smoldering gases are generated using the above-mentioned principle and generating the oxidizing agents by a separate heat generating set. In this case, a content of oxidizing agents in the cavernous body is not essential necessary.

In a third embodiment of the principle, the carbonization gases produced alone after the first or second kind, while the oxidizing agent is on the same or a different type produced in a separate generator or a Container can be removed.

In the simplest embodiment of a rocket or the like with a smoldering burner (See. The embodiment shown in Fig. i) the device consists of the Engine chamber K with a cylinder jacket T, which continues to the rear and is closed by the transverse partition Z with the discharge nozzle D. The engine chamber becomes the actual combustion chamber through the intermediate plate Z. Bk and the generator part Gt with the cavernous body S and the generator 0 of the oxidizing agent - hereinafter referred to as O generator for short - divided.

The smoldering space occupied by the cavernous body S and the O generator are in thermal contact with one another via the heat-conducting partition wall T. The oxidizing agent generated in the O generator can flow into the combustion chamber Bk through the nozzles D 1. The ignition takes place via the igniter I protruding laterally from the wall of the engine chamber K through the powder charge P, which sets the small high-calorific powder charge H on fire. As a result, a high pressure is built up right from the start, by means of which the device is pushed until the start of the generation of O and the associated start of the rocket's operation. The generation of O begins with the ignition and reaches its setpoint after a certain - as short as possible - time.

The burning carbonization gases generated by the corrosive body S, which from from the nozzle D in the middle of the intermediate plate Z, react inside the combustion chamber Bk with the oxidizing agent coming from the side nozzles D, the partition Z, which can also be drawn together to form an annular nozzle, flows. The actual combustion takes place in the combustion chamber Bk, but this is the case it is ensured that the gas pressures in the generator part Gt are always higher than in the combustion chamber Bk, because otherwise the combustion could hit back into the generator part.

In the embodiment shown in Fig. I, which is the cylindrical Carboniferous body S containing carbonization chamber from the cylindrical O-generator 0 surrounded. Within the corrosive body S, like the cross section shown in FIG shows a modified embodiment - another cylindrical O-generator OI be housed, or it can - As shown in FIG. 3 Cross-section of a third embodiment shows - four individual cylindrical Smoldering chambers with cavernous bodies S within the cylindrical, surrounding them on all sides O generator O be arranged.

Since the rocket is exposed to strong thermal loads, must be used both for the partition T and especially for the intermediate plate Z and the discharge nozzles D particularly resistant materials are used.

For devices that burn briefly, the intermediate plate Z and the discharge nozzles D graphite can be used as a material, while for longer-burning engines special cooling must be provided, for example one or the other the different types of so-called regenerative, sweat or veil cooling.

A resistant metal can be used as the material for the partition wall T - for example steel - can be used. In order to sink as evenly as possible the burning zone of the corrosive body S and the decomposition zone within the O-generator to achieve, is ensured by suitable measures that in the axial direction the hollow cylindrical partition wall T is not too much heat conduction, because this these zones in the vicinity of the partition wall T in an undesirable manner after the front End of the generator part Gt too full. To increase the radial line the partition T can be provided with ribs on both sides.

The ideal case possible in practice is shown in FIG. schematic shown, which on a partial longitudinal section of the generator part is the most appropriate respective position of the burning zone BZ of the corrosive body S and the decomposition zone ZZ within of the cylindrical 0 generator according to. the embodiment of Fig. i shows. By suitable measures in the manner of the construction of the partition wall T and the materials used here can be this desirable state without achieve further more or less completely.

The regulation was carried out in the case of the powder engines known up to now the size of the advance either gradually by adding a number of thrusters optionally more or less put into operation, or by so-called Control nozzles.

The smoldering burner engine according to the invention is imperfect Incineration worked in the Schweler, so that by increasing or decreasing the amount of the oxidizing agent supplied to the combustion chamber Bk an increase or decrease the recoil forces can be achieved.

For this purpose, for example - as shown schematically in FIG. 5 - an inner, axially displaceable O-generator 01 can be more or less in the vicinity of the combustion zone of the by means of a servo system M via a control device R controlled by the pressure sensor D f Cylindrical ring-shaped carbonization body S surrounded by a cylindrical ring-shaped 0 generator O and thereby the amount of oxidizing agent entering the combustion chamber can be controlled automatically.

However, this embodiment is in no way intended to be a limitation of the control principle. So can for example the smoldering chamber, which is partially provided with an insulating wall, can be rotated, whereby the heat flow from the corrosive body to the O-generator is changed.

It does not mean any deviation from the principle of the present invention if the combustion chamber Bk is separated from the generator part Gt, as the section according to FIG. 6 shows through a further exemplary embodiment. Here the combustion chamber Bk is connected to the carbonization chamber S and the O-generator O by separate tubular feed lines E, in which a regulating element can be installed to control the flow and possibly allow a free exit to the outside.

Instead of deriving the oxidizing agent from a fixed set of oxidizing agent carriers, it is also possible to use a liquid oxidizing agent which is contained in a liquid tank Ft (cf. it can be used beforehand in a manner known per se for regenerative cooling of the rocket or a similar drive.

The longitudinal section in FIG. 8 shows the application of the smoldering burner principle to a ramjet engine. A smoldering chamber battery SB is connected upstream of the essentially cylindrical, open furnace Bk; In front of the actual cavernous body of the individual smoldering chambers, rocket sets R can be attached to push the device. At the level of level A, liquid fuels are additionally injected into the pent-up air, which are burned in the actual open furnace Bk together with the combustion air supplied under pressure. In this way, it is possible to achieve a stable burn-up in that the hot carbonization gases act as a continuous igniter even when the ramjet engine is in unstable operation.

Claims (1)

PATENT CLAIMS: i. Rocket or similar device with combustion chamber and nozzle driven by the recoil of combustion gases, the fuel and / or the oxidizing agent being present in solid form, characterized in that the fuel and / or oxidizing agent are not mixed with one another in fine distribution, but are each separated from one another in Form more or less large pieces or volumes are provided. a. Rocket or the like according to Claim i, characterized in that the combustible gases supplied to the combustion chamber are generated in a smoldering chamber, while the preferably gaseous oxidizing agents are supplied to the combustion chamber separately from the combustible gases. 3. Rocket od. The like. According to claim i or 2, characterized in that the smoldering chamber generating the combustible gases or vapors has a substoichiometric burn-off having solid or pasty or liquid, combustible chemically uniform compounds or mixtures of such compounds, eg. B. Or hydrocarbons. Like. Contains the burn-up controlling catalysts. 4. Rocket od. The like. According to one of claims i to 3, characterized in that a flow of a fuel that melts in the heat is prevented by the addition of non-meltable substances - for example dextrin. 5. rocket od. The like. According to one or more of claims i to 4, characterized in that the smoldering burner contains polymers as fuel in which the oxygen carrier required to maintain the smoldering process is built. A rocket or the like according to claims 1 to 5, characterized in that the oxygen generator contains a small amount of fuel which maintains a manipulated smoldering or combustion sufficient to generate the gaseous or vaporous oxidant. 7. rocket od. The like. According to one of claims i to 5, characterized in that the oxidizing agent supplied to the combustion chamber is taken from an oxygen generator which is operated by the heat generated in the smoldering chamber. B. rocket od. The like. According to claim 7, characterized in that the carbonization chamber generating the carbonization gases is surrounded by a separated from it by a partition, the oxidizing agent generating generator so that the heat generated in the smoldering burner is fed through the partition to the oxidizing agent carrier is (see. Fig. i). 9. missile according to claim 8, characterized in that a 0 generator is also arranged inside the smoldering burner (see. Fig. 2). ok Rocket or the like according to claim 6, characterized in that several smoldering burners parallel to one another in a larger zero generator. are embedded (see. Fig. 3). i i. Rocket or the like according to one of Claims 6 to 8, characterized in that the partition walls between the smoldering burner and the O-generator are designed and have such a transverse thermal conductivity that the combustion zone of the smoldering burner is always approximately at the level of the decomposition zone of the O. -Generator is located (see. Fig. 4). 12. Rocket od. The like. According to claim ii, characterized in that the partitions between the smoldering burner and the O-generator are provided with ribs. 13. Rocket od. The like. According to one of claims 6 to 9, characterized in that at least one of the 0-generators is displaceable relative to the smoldering burner, whereby a regulation of the thrust generated by the exiting combustion gases is possible (see. Fig.5 ). 14. Rocket od. The like. According to claims 8 to 12, characterized in that the heat flow from the smoldering burner to the 0 generator is changed by an adjustable thermal insulation wall arranged between them. 15. Rocket od. The like. According to claim 14, characterized in that the size of the heat transfer surface between the smoldering burner and the O-generator is changed by axial rotation of the latter. 16. Rocket od. The like. According to one of the preceding claims, characterized in that the smoldering burner or burners and the generator or generators are housed in the same housing as the combustion chamber, being separated from the combustion chamber by an intermediate plate (Z) are, in which a special line to the combustion chamber is attached for each of the chambers producing the combustible gases and the oxidizing agents, so that these different gases can only come together in the combustion chamber. 17. Rocket od. The like. According to claim 16, characterized in that in the feed line of the fuel and / or the oxidizing agent to the combustion chamber, a control element controlling the flow and possibly allowing free exit to the outside is installed. 18. Rocket od.- the like. According to claim 16, characterized in that the openings made in the intermediate wall (Z) are directed in a manner known per se approximately at the center of the combustion chamber. i9. Rocket or the like according to one of Claims 1 to 18, characterized in that the smoldering charge located in the smoldering chamber is composed in such a way that the smoldering gases entering the combustion chamber are still burning or at least contain burning particles, so that the fire in the combustion chamber is maintained. 2o. Rocket or the like according to one of the preceding claims, characterized in that the carbon dioxide is covered with a preferably high-calorific fuel charge and a layer of powder, the latter being set on fire by an igniter or the like supplied from the outside through the walls for the purpose of starting the rocket can be. 21. A rocket or the like according to one or more of the preceding claims, characterized in that the oxidizing agents supplied to the combustion chamber are liquid and are taken from a special liquid tank (see FIG. 7). 22. Rocket od. The like. According to one of claims i to 2o, characterized in that liquid fuel is injected into the combustion chamber filled with gaseous or vaporous oxidizing agents from the O generator. 23. Jet propulsion according to one of the preceding claims, characterized in that a plurality of carbonized bodies combined to form a battery are used as a stagnation jet engine (see FIG. 8). 24. Jet propulsion according to claim 23, characterized in that the smoldering sets are covered by rocket sets whose burn-off is used to push the device. 25. Jet propulsion according to claim 23 or 24, characterized in that liquid fuels are additionally injected into the combustion air flowing into the combustion chamber in front of the nozzles of the corrosive body battery. Considered publications: German Patent Nos. 941 io2, 618668, 6o8242, 484o64, 248 4i 9; Swiss Patent No. 279 732; French Patent Nos. i 077 744 i o52 196; U.S. Patent Nos. 2714: 286, 2544419-